Anti-galling method for treating materials

ABSTRACT

An anti-galling method for treating materials, which provides for subjecting at least one of the at least two components mutually coupled with at least one degree of freedom, made of metallic material, to a first preliminary step of thermal treatments to increase surface hardness and to a second preliminary step of surface grinding. The method further includes the steps of: washing at least one portion of the surface of the at least one component subjected previously to the preliminary steps; shot peening the at least one portion of the surface of the at least one component previously subjected to washing; and applying a layer of molybdenum disulfide to the at least one portion of the at least one component previously subjected to shot peening.

TECHNICAL FIELD

The present disclosure relates to an anti-galling method for treating materials.

BACKGROUND

Two mechanical bodies that slide with respect to each other during their normal operation can be subject to a phenomenon known as galling

The term “galling” normally refers to the occurrence of locking of two or more complementary moving mechanical members due to excessive sliding friction, which causes the consequent temporary or permanent interruption of their regular operation.

Said galling can be due to various reasons, which lead to a single consequence: excessive overheating of the propulsion unit. For example, galling can be caused by lack of lubrication, by excessive stress at full power is and prolonged over time (caused for example by an operating rate that is higher than the actual capability of the machine) or by incorrect play between the parts (an excessively small play between the bushing and the respective pivot, for example, can cause an interruption of the lubricating film; an excessive play does not allow correct segregation of the lubricant, if any, and can generate impacts between the components).

Between coupled components in reciprocal motion there is generally a lubricant (grease, oil or specific emulsions), although numerous mechanical couplings in which no lubricant is used are provided.

In principle, the present disclosure relates preferably to any pivot-bushing assembly the components of which are made of a metallic material (for example steel, aluminum and alloys of another type) with a reciprocal rotary motion.

In this type of assemblies, galling often occurs which causes machine downtime and evident damage of the pivot.

In order to obviate these drawbacks, lubricants are often interposed between the pivot and the bushing (within the play between them) and segregated therein by means of specific sealing elements.

In some cases, however, the lubricant may not be sufficient to avoid galling, especially after many hours of operation.

Accordingly, assemblies of the known type are particularly subject to galling and in order to avoid its onset periodic maintenance is provided which is aimed at checking the state of the lubricant arranged in the play between the pivot and the bushing and at restoring its ideal conditions.

Therefore, assemblies of the known type are subject to galling phenomena and, if one wishes to avoid the occurrence of this phenomenon, which would cause machine downtime, frequent and expensive periodic maintenance of the assemblies is necessary.

In order to reduce the onset of galling, it is known to resort to the execution of different types of thermal treatment on pivots made of quenched and tempered steel, at the end of which the surface of said pivot is subjected to grinding.

Even after subjecting them to these treatments, the pivots remain in any case subject to the phenomenon of galling and therefore a long service life of the same cannot be ensured.

SUMMARY

The aim of the present disclosure is to solve the problems described above, proposing an anti-galling method for treating materials that allows minimizing the onset of galling to the point of making it even negligible.

Within the scope of this aim, the disclosure provides an anti-galling method for treating materials that makes it possible to minimize the risk of galling of a pivot intended to be turned with respect to a bushing that is mated with it.

The disclosure further provides an anti-galling method for treating materials that ensures a reduction of the periodic maintenance of the mechanical couplings that comprise components subjected to said method.

The present disclosure also provides an anti-galling method for treating materials that has low costs, is relatively simple to provide in practice and is safe in application.

This aim and these and other features that will become more apparent hereinafter are achieved by providing an anti-galling method for treating materials, which provides for subjecting at least one of the at least two components mutually coupled with at least one degree of freedom, made of metallic material, to a first preliminary step of thermal treatments to increase surface hardness and to a second preliminary step of surface grinding, which comprises the following steps

-   -   performing a first step of washing at least one portion of the         surface of the at least one component subjected previously to         the preliminary steps;     -   performing a second step of shot peening said at least one         portion of the surface of the at least one component previously         subjected to washing;

and

-   -   performing a third step of applying a layer of molybdenum         disulfide on said at least one portion of the at least one         component previously subjected to shot peening.

BRIEF DESCRIPTION OF THE DRAWINGS

Further characteristics and advantages of the disclosure will become more apparent from the description of a preferred but not exclusive embodiment, of the anti-galling method for treating materials according to the disclosure, illustrated by way of non-limiting example in the accompanying drawing, wherein FIG. 1 is a sectional front view, along a transverse plane, of a possible rotatable mechanical coupling provided by applying the anti-galling method according to the disclosure.

DETAILED DESCRIPTION OF THE DRAWINGS

With particular reference to FIG. 1, the numeral 1 generally designates a possible rotary mechanical coupling provided by applying the anti-galling method for treating materials according to the disclosure.

The method according to the disclosure can be applied to mechanical couplings between which there is at least one degree of freedom.

Said components are preferably made of metallic material: by way of example, mention is made of metallic alloys, such as steel, or metals substantially in the pure state, such as aluminum If reference is made to components made of steel, quenched and tempered steel will generally be used.

The anti-galling method according to the disclosure entails subjecting at least one of the at least two components to a first preliminary step of thermal treatments to increase surface hardness and to a second preliminary step of surface grinding.

The two preliminary steps are the ones normally applied in the background art.

The method according to the disclosure provides for the execution of additional consecutive steps on the at least one component.

It is in fact necessary to perform a first step of washing at least one portion of the surface of the at least one component previously subjected to the preliminary steps.

It is then necessary to perform a second step of shot peening of at least one portion of the surface of the at least one component previously subjected to washing.

Finally, the process requires the execution of a third step of application of a layer of molybdenum disulfide on the at least one portion of the at least one component previously subjected to shot peening.

It is useful to specify that the first washing step also comprises a surface degreasing of the at least one portion of the surface of the at least one component previously subjected to the preliminary steps.

Degreasing involves removing any trace of grease or dirt from the surface of the component (generally made of steel) before subjecting it to subsequent treatments (mechanical, thermal, etcetera) or to surface finishing. It is important to remove traces of grease and dirt, because the presence of organic molecules, being constituted essentially by carbon, can be dangerous: the carbon may in fact enter the matrix of the material during a thermal treatment, if performed (some mechanical treatments that generate heat also can cause the migration of the carbon contained in the grease that is present on the external surface of the part being machined), causing an aesthetic damage to the part and most of all a local degradation of its characteristics. Carbon enrichment can affect negatively the mechanical properties of the part by hardening and embrittlement, even reducing its corrosion resistance.

Degreasing can be performed with organic solvents by utilizing the chemical principle according to which “like dissolves like” or with alkaline or acid solvents in an aqueous base. In this second case, one acts on the hydrophilic part of the compound.

The second step of shot peening the at least one portion of the surface of the at least one component previously subjected to washing is extended to obtain, in said at least one portion, a state of residual compression with a value comprised between 200 MPa and 10000 MPa: the ideal value of residual compression that can be obtained for correct execution of the method according to the disclosure is approximately 1100 MPa.

Shot peening is an operation that includes surface cold hammering by means of a violent jet of spherical shot, or of cylindrical shot obtained by cutting a wire (known as cut-wire shot).

The machines that perform this treatment, i.e., peening machines, propel the jet of rounded or cylindrical shot toward the parts to be machined by means of one or more rapidly rotating impellers, generally centrifugal ones, or by means of compressed air; in any case, the materials used for the grit can be cast iron, steel, glass and, more rarely, ceramics.

Moreover, shot peening improves the distribution of the surface tensions that has been perturbed by mechanical treatments and/or thermal treatments and attenuates the concentrations of efforts produced by notches, threads, decarburization, etcetera.

Shot peening, as regards the manners of execution, resembles sanding, while for its intended purpose it is more similar to rolling, since it acts more on plasticity than on abrasion.

It causes in fact a surface compression, since its jet induces a plastic deformation that propagates to a depth of a few tenths of a millimeter in the material being considered and technically it serves to improve the distribution of surface tensions, increasing the fatigue strength of the treated part.

This effect is due to the residual compressive tensions that it causes in the surface of the material and in the underlying layers, which are able to is reduce the internal tensions when the part is subjected to stresses. The material is thus rendered more resistant to fatigue stresses.

At the end of the treatment, due to the micro-cavities that are generated and are mutually superimposed, one has, as a secondary effect, also a reduction in the quantity of light reflected on the material, i.e., a sort of satin finish.

The effect of shot peening depends, if the nature of the shot peened material remains constant, on the hardness and size of the shot, on the flow-rate, on the velocity and angle of impingement of the stream, on the distance of the part from the projection system, on the intensity and on the coverage. Shot peening intensity, measured in Almen degrees, is evaluated by the curvature undergone, in the direction of incidence of the stream, by one of the two faces of a laminar test piece (76×19 mm) obtained from C 70 UNI 7845 killed steel hardened and tempered at 44÷45 HRC, the thickness “s” of which can assume three different values that correspond to shot peenings of weak intensity N, medium intensity A, and strong intensity C. The curvature, produced by the stream of shot, is measured with a quadrant comparator.

Coverage is determined by subjecting a polished test piece to a stream of shot for a time that corresponds to the associated intensity and by measuring, with a 50× magnification, the areas of all the impinged regions located within a circumference having a conventionally set diameter; coverage is defined as the ratio between the sum of the areas of the impinged regions and the area of the circle.

This second step of shot peening of the at least one portion of the surface of the at least one component subjected previously to washing is performed with S110 steel balls with a diameter comprised between 0.01 mm and 1.5 mm: preferably, balls are adopted which have a diameter equal to approximately 0.3 mm, a value for which an optimum result of the treatment in the method according to the disclosure has been observed.

It should also be noted that the second step of shot peening of the at least one portion of the surface of the at least one component subjected previously to washing is performed with an intensity between 4 and 40 Almen degrees referred to a type A test piece (i.e., peening of medium intensity identified by the letter A).

In this case also, it is deemed appropriate to specify that the ideal value of peening intensity, expressed in Almen degrees and referred to peening of medium intensity identified by the letter A, is approximately 6 or 8.

In any case, said second step of shot peening is performed by providing a coverage of more than 60%, although optimum results are achieved with 100% coverage of said at least one portion.

The third step of the method according to the disclosure, which corresponds to the application of a layer of molybdenum disulfide on the at least one portion of the at least one component, entails the provision of a layer with a thickness comprised between 1 and 50 μm.

In this case also, it is convenient to specify that ideal thicknesses of molybdenum disulfide, within the scope of the method according to the disclosure, are between 5 and 15 μm.

It should be noted that the third step of application of a layer of molybdenum disulfide on the at least one portion of the at least one component provides for the aspersion, on said portion, of an aerosol comprising molybdenum disulfide in a percentage by weight of more than 10%, inorganic resins, solvents and propellants.

It is preferable to adopt aerosols in which the molybdenum disulfide percentage is higher than 20% in order to obtain better results and a more efficient and stable layer on the treated portion of the component.

The combination of the steps indicated and provided by the method according to the disclosure is particularly effective, since surface cleaning defines ideal conditions for the adhesion of the molybdenum disulfide layer.

At the same time, the shot peening step generates on the outer surface of the component a plurality of contiguous micro-concavities.

This surface irregularity facilitates the adhesion of the molybdenum disulfide, ensuring that deposits of even higher thickness are produced locally which increase its structural strength.

Furthermore, it is evident that with respect to a same smooth surface, the surface affected by a plurality of contiguous concavities without discontinuity has a larger area, thus extending the regions of contact between the molybdenum disulfide and the surface itself the toughness of the adhesion of the molybdenum disulfide is directly proportional to the area of the surface that is coated and therefore an irregular surface produces a higher stability of the stratification.

Finally, the residual tension produced by the shot peening step ensures higher rigidity of the surface of the component.

A component that is less subject to deformations is certainly more suitable to be subjected subsequently to the deposition of a layer of rigid material, since deformations might cause layer separations.

The combination of the steps entails therefore an overlap of the indicated effects and also a synergistic combination thereof which ensures a strength of the layer of molybdenum disulfide and also an effectiveness of the mechanical coupling that is surprising in terms of durability and mechanical performance.

It should be noted that the method according to the disclosure also provides for the optional execution of an additional auxiliary step of removing material in the other of the two mutually coupled components, in order to increase play between them.

The removal of material, in this case, occurs at at least one region of the other component that does not face and is proximate to the at least one portion subjected to the first to third steps.

The removal of material makes it possible to ensure that sliding between the two (or more) components occurs exclusively at the portions subjected to the method: the other parts in fact are separated by considerable play, which is obtained with the further removal of material provided in the auxiliary step cited earlier.

Moreover, the increase in plays makes it possible to contain a larger quantity of lubricant (oil or grease) within said plays. The lubricant is segregated within the free space (play) that is present between the components by means of respective sealing elements of the traditional type, for which the provision of any specific description is not deemed necessary (since they are known).

According to a particular application of the method according to the disclosure, which makes it possible to simply and immediately identify its numerous advantages and considerable potentials, a first component is constituted by a pivot 2 and a second component is constituted by a bushing 3.

The pivot 2, in the configuration for use, is inserted rotatably within the bushing 3 and defines a sliding of its at least one portion 4, subjected to the first to third steps, on corresponding areas of the internal surface of the bushing 3.

In turn, the bushing 3 is machined with removal of material on a part of its internal surface in order to define a region 5 of the cavity formed by it that has a larger diameter.

In this manner it is possible to identify a play 6 (which can also have considerable dimensions) between the pivot 2 and said region 5 of the bushing 3.

Within the play 6, a predefined quantity of lubricant can be segregated which facilitates the mutual rotations of the pivot 2 and the bushing 3.

FIG. 1 refers to a possible coupling of links of a chain that are mutually articulated.

Analyzing specifically the constructive solution given by way of example, the links 7 and 8 of the chain in this case are keyed on the bushing 3 with a predefined interference.

Likewise, two other chain links 9 and 10, opposite the ones that are integral with the bushing 3, are keyed, again by adopting a predefined interference, on the pivot 2.

In practice, according to the configuration defined previously, the assembly of the pivot 2 and of the links 9 and 10 constitutes a first joint part and the assembly of the bushing 3 and of the links 7 and 8 constitutes a second joint part.

The two joint parts constitute the mechanical coupling, which can be particularly efficient if the portions 4 of the pivot 2 that are intended to slide on the internal surface of the bushing 3 have been subjected to the method according to the disclosure.

Finally, it is specified that in order to ensure the necessary segregation of the lubricant in the play 6 defined between the pivot 2 and the region with larger diameter of the cavity inside the bushing 3, sealing elements 11 and 12 are used between the pivot 2 and the bushing 3.

Chains of the type shown in FIG. 1 are used universally in earth-moving machines and in many other industrial processes.

The method according to the disclosure can be applied in any case to a considerable number of other mechanical couplings and joints which, due to the mechanical tensions applied and/or to the speed and frequency of the mutual movements, are normally subject to galling

Advantageously, the present disclosure solves the problems described earlier, proposing an anti-galling method for treating materials that allows minimizing the onset of galling to the point of even rendering it negligible.

This result is achieved by the synergistic effect of the residual state of compression induced by the shot peening step and by the presence of a layer of molybdenum disulfide.

Usefully, the anti-galling method according to the disclosure allows minimizing the risk of galling of a pivot 2 intended to be turned with respect to a bushing 3 that is mated therewith, thus being particularly effective in the case of rotary couplings.

Efficiently, the anti-galling method according to the disclosure ensures a reduction in periodic maintenance of the mechanical couplings comprising components subjected to said method.

In fact, the reduced onset of the galling phenomenon and the presence of a greater play 6 (with respect to couplings of the traditional type) ensures a drastic reduction of the number of required maintenance interventions.

Favorably, the anti-galling method according to the disclosure can be performed with substantially low costs, is relatively simple to provide in practice and is safe in application.

The disclosure thus conceived is susceptible of numerous modifications and variations: all the details may furthermore be replaced with other technically equivalent elements.

In the examples of embodiment shown, individual characteristics, given in relation to specific examples, may actually be interchanged with other different characteristics that exist in other examples of embodiment.

In practice, the materials used, as well as the dimensions, may be any according to the requirements and the state of the art. 

1.-10. (canceled)
 11. An anti-galling method for treating materials, which provides for subjecting at least one of the at least two components mutually coupled with at least one degree of freedom, made of metallic material, to a first preliminary step of thermal treatments to increase surface hardness and to a second preliminary step of surface grinding, which includes the following steps: performing a first step of washing at least one portion of a surface of the at least one component subjected previously to the first and second preliminary steps; performing a second step of shot peening said at least one portion of the surface of the at least one component previously subjected to washing; and performing a third step of applying a layer of molybdenum disulfide to said at least one portion of the at least one component previously subjected to shot peening.
 12. The anti-galling method according to claim 11, wherein said first washing step also comprises surface degreasing of the at least one portion of the surface of the at least one component subjected previously to the preliminary steps.
 13. The anti-galling method according to claim 11, wherein said second step of shot peening said at least one portion of the surface of the at least one component previously subjected to washing is prolonged until a state of residual compression with a value comprised between 200 MPa and 10000 MPa is obtained in said at least one portion.
 14. The anti-galling method according to claim 11, wherein said second step of shot peening said at least one portion of the surface of the at least one component previously subjected to washing is performed with S110 steel balls with a diameter comprised between 0.01 mm and 1.5 mm.
 15. The anti-galling method according to claim 11, wherein said second step of shot peening said at least one portion of the surface of the at least one component previously subjected to washing is performed with an intensity whose value is comprised between 4 and 20 Almen degrees referred to a type A test piece.
 16. The anti-galling method according to claim 11, wherein said second step of shot peening said at least one portion of the surface of the at least one component previously subjected to washing is performed with a coverage of more than 60% of said at least one portion.
 17. The anti-galling method according to claim 11, wherein said third step of application of a layer of molybdenum disulfide on said at least one portion of the least one component provides for the creation of a layer with a thickness comprised between 1 and 50 μm.
 18. The anti-galling method according to claim 11, wherein said third step of application of a layer of molybdenum disulfide on said at least one portion of the at least one component provides for the aspersion, on said at least one portion, of an aerosol comprising molybdenum disulfide in a percentage by weight of more than 10%, inorganic resins, solvents and propellants.
 19. The anti-galling method according to claim 11, wherein an auxiliary step of removing material in the other one of the two mutually coupled components to increase the play between them, said removal of material taking place in at least one region of said other component that does not face and lie proximate to said at least one portion subjected to the first to third steps.
 20. The anti-galling method according to claim 11, wherein a first component is a pivot and a second component is a bushing, said pivot, in the configuration for use, being inserted rotatably within said bushing and defining a sliding of its at least one portion, subjected to the first to third steps, on corresponding areas of an internal surface of said bushing. 